DE35981C - Innovations in engines with rotating cylinders - Google Patents

Description

IMPERIAL

PATENT OFFICE.

CLASS 14: Steam Engines.

The innovations consist essentially in a special arrangement of the axes of rotation of the rotating cylinder F ¹ and the flywheel C ¹ and in certain individual constructions in this arrangement.

In the accompanying drawings shows:

Fig. Ι the machine in front view;

FIG. 2 the same in longitudinal section according to AB, FIG. 4;

3 shows the vertical section through the cylinder according to CD, FIG. 2;

4 shows the section transversely through the cylinder according to EF, FIG. 1, with the expansion device omitted;

5 shows the section GH, FIGS. 4 and 6, and simultaneously with FIG. 6 the expansion device variable by means of the regulator;

7 shows the section NM and

8 shows the section JK through the steam stand D ¹ , FIG. 4.

FIGS. 1 and 11 represent a second variable expansion device, specifically FIG. 1 is the section according to OPQ.-R, FIG. 11.

The same letters mean the same machine parts in all figures. A ¹ is the foundation plate with the main bearings, B ^{1 is} the flywheel shaft, C ^{1 is} the flywheel, D ^{1 is} the steam stand screwed onto the base plate .A ¹ and E ^{1 is} the pulley; F ¹ are double cylinders which have steam ducts / and Z ¹ shared at the top and bottom and rotate in a circle around an axis α passing through the middle between the two. This axis α is made in one piece with the steam stand D ¹ , but it can also, made by itself, be fastened in the steam stand, FIGS. 2, 3 and 4.

The two steam pistons b are connected by means of the two piston rods c and the crosshead d to the engagement bolt e of the flywheel C ¹ , FIGS. 1, 2 and 3. The steam stand D ^l is made so that the axis a is half as much Piston stroke is removed from the center of the flywheel C ¹ , namely here vertically below the same, Fig. 2 and 3, so that with a half turn of the flywheel C ¹ the piston b pass through the entire length of the cylinder and with a further half turn of the flywheel in the same direction up to the previous level of the same, a second full piston stroke is completed in the opposite direction. Accordingly, the pistons always transmit the pressure exerted on them at an acute angle (in relation to the flywheel axis) to the attack bolt e of the flywheel, which angle is only subject to slight changes, with the exception of the dead points. The speed of rotation of the flywheel is therefore very uniform in the individual moments of rotation even if the flywheel is lighter, as can be seen from FIG. In this figure \ forms the center of the flywheel and s the fulcrum of the cylinder, e is the attack bolt, which moves towards u . If now ew is tangent in e, which can be regarded as coinciding with the small arc ev , and if e ν is perpendicular to it, then angle χ is equal to angle J ^; accordingly the triangles evu and eot are similar

borrowed, so that uv: eu - ο t : e ο or u ν X e ο = eu χ ο ί.

If e ο is now assumed to be the measure of the mean piston pressure, ot is the mean tangential pressure, while u ν means the progress of the piston made during this movement and eu the circular path traversed. If one now substitutes these meanings in the above formula: uv ~ X.eo = eu><ot , one obtains the result that the product of the path covered by the piston and the mean piston pressure is equal to the product of the resulting piston Tangential pressure and the space traversed by point e. The. So power is transmitted very evenly.

The pressurized steam is conducted through the inflow pipe f, ^{Fig. 1} , 2, 5 and 6 located in the foundation plate A 1, into the vertical part of the channel jf, Fig. 5, of the steam stand D ¹ , from where it flows through the lateral openings of the Expansion valve g, Fig. 4 and 5, in the horizontal part f ^{2 of} the channel just mentioned, Fig. 4, reaches up to the control member. The steam distribution takes place there, -where the slide disk h , which is screwed tightly to the double cylinders, with its circular surface adjoins the likewise circular surface of the steam stand D ¹ , FIGS. 2 and 4.

In the surface of the steam stand D ¹ is the mouth of the inflow ^{channel / "2} , Fig. 4 (dotted in Fig. 5), and the beginning of the outflow channel i, Fig. 2, 4 and 5. The shape of these channels and the surface of the steam stand can be seen in larger scale Fig. 8. The shape of the slide disk h is shown on a larger scale in Fig. 7. Since the sections JK and JVM, Fig. 4, are very close to the contact surface, one can see one another Fig. 8 as the fixed slide mirror of D ^] and Fig. 7 as the slide surface of the disk h .

In the disk h attached to the double cylinders are the two openings k and k \ Fig. 2 and 7, of which the former with the upper cylinder ^{inflow channel / and the latter with the lower cylinder inflow channel Z 1} communion, Fig. 2 and 3. Since the channel / branches off at the top to both cylinders and the channel I ¹ branches off at the bottom to both cylinders on the right and left, so the opening k, Fig. 2, 3 and 7, forms the common inflow opening of both cylinders for the upper side of the piston and k ^l the common inflow opening of both cylinders for the lower side of the pistons.

If one thinks that Fig. 8 is placed on Fig. 7, so that the outflow opening i is on the left hand, then the channels k and k \ Fig. 7 will be closed. If now Fig. 7 were rotated in the direction of the arrow, then k will connect with y ² and k ¹ with i and let in the steam or. the previously used steam can be released. After a quarter turn, k any ^{2 will be} over when ^{2 are} closed, whereas during a further quarter turn k ^x still remains in contact with i , so that the steam can flow out during the entire piston stroke. The machine then works with less than half the cylinder filling. If you want to work with less filling, the openings kk ^l and / ^{2 must be} correspondingly shorter and i longer, and vice versa. For full print one would z. B. come to the point that all four openings would be of the same length. An approximately desired lengthening of kk ^l and / ² and shortening of i would have to take place as indicated by the dotted line.

The device for variable expansion consists of the eccentric, which forms one piece with the disk h , Fig. 4, 5 and 7, and the eccentric ring m, Fig. 1, 2, 4, 5, 6 and 7, which with the coulisse n ^{l of} the lever η is connected by pin r and Coulissenstein, FIGS. 5 and 6. The reciprocating movement of the eccentric ring m, which is moved by the disk h, the periphery of which is eccentric, FIGS. 1, 2, 4 , 5, 6 and 7, sets the lever n connected to it by the pin r and coulisse stone, Fig. 5 and 6, in vibrations, whereby the knee joint ο is moved back and forth in such a way that it is one with every half revolution of the cylinder Deflection to the right or left makes, whereby the rod ρ (which in turn is connected by a side arm to your knee joint 0) and with it the lever q respectively. the associated expansion valve g is moved up and down, FIGS. 5 and 6. The valve consists of a hollow cylinder g which moves in a stationary cylinder g ^1. Both cylinders have lateral openings which, when they correspond to one another, allow the steam to pass through, which then finds its way to the steam valve. The eccentricity on the valve disk h is now set in such a way that the connection of the openings in the two hollow cylinders g and g ¹ always takes place in good time and the same is done sooner or later by lifting the eccentric ring m. The latter is brought about by the fact that the hollow cylinder g has a sufficiently dead passage downwards, whereby it is made possible that the steam openings correspond only for the period in which steam is to flow in. In order to achieve this reliably, the expansion already brought about by the arrangement in FIGS. 7 and 8 comes to the rescue. That power

it is possible that the inflow opening f ² in D ¹ can be filled with steam earlier without the steam being able to get into the cylinder ducts through the valve disk h as long as the openings k and k ^{1 are} closed. The earlier the lateral openings in the hollow expansion cylinder g open, the earlier they have to close again, since the course of the eccentric always remains the same. By lifting the point of application of the eccentric ring at r in the coulisse η ^{1 of} the lever η by means of the rod s , Fig. Ι, 5 and 6, this earlier or later opening and closing of the expansion valve g is achieved by the regulator.

Another type of this device for variable expansion, which allows less opening and earlier closing of the expansion valve g, or the reverse, is achieved in that, as shown in FIGS. 10 and 11, the pivot point of the lever q is centered through the regulator rod s Rotating the small eccentric t and the lever t ^l attached to it is lowered. Since the rod ν is displaceable in the guide in the foundation and the loop v ^{1 surrounds} the eccentric t , Figs the expansion valve g is already forced to go down significantly lower at the slightest lowering of the pivot u of the lever q and thus shuts off the steam much earlier. The eccentric ring m transmits its movement in this device, Fig. Ι ο and 11, on the lever »>, on its shaft w ^l and through this to the knee joint 0, from where the movement to the lever q and on to the expansion valve g is transmitted. In order to change the movement of the knee joint 0, the lever n> has a slot to move the point of application ψ ¹ . The lever i ² , which is attached to the shaft of the small eccentric t ^{, carries the counterweight i 3} on the vertical rod connected to it, which always brings the eccentric into its old position as soon as the regulator sinks.

The adjustability of the cylinder bearing χ in FIGS. 2, 3 and 4 is shown in more detail in FIGS. 12, 13 and 14. The two bearing halves each have a wedge-shaped projection 1, FIGS. 12 and 13, which is fitted into an incision in the bearing cavity in the cylinder piece in such a way that the bearing halves move perpendicularly closer to one another by moving them in the longitudinal direction. To achieve this, the oval plate 2, Fig. 2, 4, 12, 13 and 14, is fastened to the bearing halves by means of two countersunk screws 3, Figs. 12 and 13. The holes for receiving the screws in the plate 2 are oval so that the bearing halves can be moved. The plate 2 is pushed forward by means of the adjusting screws 4, which have their nut thread in the plate 1 itself and are supported with their lugs against the disk 5, FIG that the bearing means must remain exactly in its place. The plate 5 is supported against plate 6, Fig. 2, 4, 12 and 14, which through the head of the bolt jr, which passes through the axis of the steam stand D ¹ and on the front side by the spring y ¹ , Fig. 1 , 2 and 4, is held. The spring jK ^{1 also} has the purpose of attracting the cylinder with the slide disk h elastically and tightly to the steam stand -D ¹ .

The cover plate 7, Fig. 2, 4, 12, 13 and 14, fastened by means of the screws 8, closes the device just described vapor-tight on the flywheel side so that the lubricating oil cannot escape through the lubricating holes 9, Fig. 12. To the front, the bolt is ^{sealed by the stuffing box ^ 3} , Fig. 1, 2, 4 and 6 and is prevented from rotating by the hexagon located in the pin α of the steam stand D ^1; also the washer 6, because the hexagonal bolt head is embedded in this plate, FIGS. 12 and 14.

So that no steam is anschliefst at the location where the disc h to the mirror of the steam stand D ^1, can contact aufsen after, the controller is sealed by a kind of stuffing box, Fig. 2, 4, 6 and 11. These shall look of the metal ring ^, Fig. 2 and 4, which is received by the annular pressure cover ^ ¹ , in such a way that it lies with its one surface tightly against the disk h and on the other side against the packing gland, which is in the free space of ^ ¹ is located. The pressing of the ring ^ ¹ is done by the pressure screws ^ ³ , Fig. 1, 2 and 5 installed in the steam stand. The imaginary rings are prevented from turning by spring wedges.

The shape of the flywheel C ¹ is chosen so that the cylinders can lie within the flywheel rim, so that not only the lubricating oil or water is prevented from splashing out into the engine room, but also the center of gravity of the flywheel with that of the cylinder and with ' the point of attack e, Fig. 2, falls fairly close in a plane.

Of course, water can also be used as a driving force instead of steam, if the machine is so designed that it works without expansion. The machine can also work with condensation if a condenser with air pump is added to it will.

In Fig. 15 the machine is shown as a compound machine. The arrangement is such that on one side the double cylinders F ¹ absorb the high-pressure steam which, after it has acted in these cylinders, through the outflow pipe i ¹ into the receiver G and from there through the inflow pipe f into the low-pressure double cylinders F ² flows in, from where it then flows through the outflow pipe z ² into the open air or into the condenser H , from which the water is removed by the air pump J. The two flywheels C ¹ and C ² have a common main shaft S ¹ , from which the air pump J, the regulator K and the rope or pulley L are driven.

The eccentric ring for the variable expansion is denoted by m , the device for variable expansion itself is not shown; it can be the same as in FIGS. 5 and 6 or 10 and 11, but is only to be attached to the side of the high-pressure cylinder F ^1.

Each side of the compounding machine, FIG. 15, is completely identical in its arrangement Construction, like the machines shown in FIGS. 1, 2, 3 and 4.

Claims (1)

Patent Claims: i. In engines with rotating cylinders, the arrangement of two identical and equally acting power cylinders F ¹ with an interposed, eccentric and parallel to the flywheel axis B ¹ lying axis of rotation a, for the purpose of uniform mode of attack and power transmission with the most constant angle of attack. With the arrangement described under 1.: The combination of the slide track firmly connected to the supply stand D ¹ and provided with openings ^{y 2} and i with the control disk h attached to the rotating cylinders F ¹ and provided with openings k and k ^l , for the purpose of allowing propellant to enter above or below the piston allow.
The combination of the eccentric disk m and the coulisse lever η with the knee joint 0, for the purpose of achieving an expansion that can be changed by the regulator by raising or lowering the point of application r. The combination of the eccentric disc m which ν s beeinflufsten support rod through the regulator rod and, to achieve the knee 0 for the purpose of raising or lowering the through ν supported pivot point and a variable by the regulator expansion. The combination of the bearing shells xx, which are provided with rising surfaces in the longitudinal direction, for the purpose of achieving an all-round and uniform approach of the surrounding surfaces to the axis of rotation by moving them in this direction. In addition 3 sheets of drawings.